KR101619094B1 - Plate heater for high temperature baking apparatus - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a substrate heater employing a terminal block having a function of preventing heat deformation and power supply from being heated in a high-temperature baking apparatus, and in heating a semiconductor wafer or a glass substrate, A substrate heater is employed which employs a terminal block which simultaneously fixes hot wire and electric power for preventing the phenomenon of loosening of the hot wire of the terminal block due to thermal expansion and the distortion of the terminal block.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a substrate heater for a high-temperature baking apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a substrate heater employing a terminal block that simultaneously applies heat prevention and power supply for preventing warpage in a high-temperature baking apparatus, and is characterized in that when heating wires are attached to a substrate heater for heating a semiconductor wafer or a glass substrate, To a substrate heater which employs a terminal block which simultaneously fixes hot wire and electricity to prevent the phenomenon that the fixing part of the terminal block is loosened due to thermal expansion and the distortion of the terminal block.

The high temperature baking apparatus used in semiconductors and FPD (flat panel display) / OLED (organic light emitting display) / LCD (liquid crystal display) processes is required to have durability because of uniformity of temperature and long process life. The baking apparatus currently used in the pre-process and post-process of the semiconductor is a method in which a heat insulating substrate having a hot wire is mounted on the lower half of the metal plate, and the heat is distorted due to thermal distortion of the metal plate, Problems such as disconnection, electrical connection failure due to loosening of the terminal block and the hot wire connecting portion occur.

As shown in Patent Document 1, the metal plate material is improved by replacing the metal plate material with a ceramic material having a good thermal conductivity and a small thermal expansion coefficient and being improved when the metal plate is twisted at a high temperature for a long period of time. We are trying to solve the problem in the same way as direct printing. However, problems such as screw loosening of the terminal block and the hot wire connecting part which are frequently occurred in high temperature heating and poor electrical connection due to disconnection are fatal to the durability of the baking device, but attempts to improve it are rare.

1. Korean Patent Publication No. 10-2013-0098086 (Mar.

In order to solve the above problems, the present invention provides a method for solving problems such as twisting of a terminal block and a hot wire connecting portion and poor electrical connection by using a terminal block which simultaneously fixes a hot wire and electric power to a substrate heater of a high temperature baking apparatus do.

A substrate heater of a high-temperature baking apparatus for use in a semiconductor or display process according to the present invention for solving the above-mentioned problems is characterized by comprising: a heat-insulating substrate having a pattern groove formed on one surface thereof with a heat- And a protection board connected to upper and lower ends of the heat insulating board to protect the heat insulating board and to insulate the heat insulating board from the terminal board. Wherein the bolt head of the terminal block has an angular shape and grooves having the same angular shape are formed on the protective board so as to prevent the bolt head from protruding when the nut is fastened and to prevent the bolt head from being loosened by thermal deformation using a double nut .

And the double nut is fixed with threads having different directions.

And a plurality of temperature sensors are attached to the upper portion of the thermally conductive substrate, and the temperature of the substrate is controlled by a temperature controller having a feedback circuit.

And the hot wire is formed of nickel or a nickel alloy.

The heat insulating substrate and the protection substrate are mica.

And the thermally conductive substrate is AlN.

The angled bolt head and the supporting base are made of a metal or an alloy of the same kind as the hot wire, and the through hole of the screw is formed in consideration of the thickness of the heat insulating board under the bolt head.

The heat insulating substrate is not limited to a mica, and the heat ray is adhered or uniformly adhered to the outside from the inside to the outside along a pattern formed on the heat insulating substrate with a heat ray diameter size.

The high-temperature substrate baking apparatus for a semiconductor fabrication facility includes a substrate heater, a thermally conductive substrate, a temperature control unit, a temperature sensor, a power supply unit, and a case having a control display unit and a plurality of connection members including a terminal block .

The baking apparatus has a separate chamber and is used in air or vacuum.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a substrate heater of a substrate baking apparatus used in a semiconductor process, and it has an effect of improving the durability of a substrate heater by removing the cause of a faulty electrical connection of a terminal block, .

A substrate heater with a hot wire according to the present invention uses a mica which is 50% cheaper than a ceramic heater, is easy to process, and has excellent durability at high temperatures. Therefore, the present invention is advantageous from the viewpoints of productivity and economical efficiency of the baking apparatus, and is a very useful invention for real life or industrial use.

1 is a perspective view of a substrate heater;
2 is a cross-sectional view of a terminal block having through holes assembled in a substrate heater;
3 is a perspective view of a terminal block.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The drawings illustrate only the essential features for the sake of clarity of the invention and are not to be construed as limiting the drawings.

The high temperature used in the present invention refers to a temperature of 400 DEG C or higher, but is not absolute but is a concept conventionally used in a semiconductor baking process.

A high-temperature baking apparatus having a baking temperature of 400 to 500 占 폚 used in a semiconductor process includes a heat insulating substrate 1, two protective substrates 3 and 4, a heat wire 2, a thermally conductive substrate 15, a power supply unit, A control display portion, and a baking device case, and further includes a plurality of assembling members such as a terminal block.

The substrate baking apparatus is used to dry a semiconductor wafer or glass substrate or to cure the sensitizing solution applied for light or electron beam lithography.

The insulating substrate, the two protective substrates, and the thermally conductive substrate have the same alignment mark and a plurality of joint through-holes for the two types of joining screws formed on the outside of the substrate. In addition, the upper surface of the protective substrate is a bolt head pattern For the lower surface, through-holes of the same size are formed at the same position as the terminal-unit mounting through-hole at the edge of the substrate.

The heat insulating substrate uses a substrate made of a material such as a mica or a ceramics, but a mica is advantageous in terms of economy. The mica is excellent in fire resistance and excellent in electrical insulation, and is relatively good in workability and is widely used as a heat insulating material for electric heaters in general. The size of the mica substrate is usually made larger than the size of the semiconductor or glass substrate to be heated, and the thickness is selected in consideration of the thickness of the hot wire.

The pattern to which the hot wire is attached is formed through an etching process or etching. At this time, the depth of the pattern is formed considering the diameter of the heat ray.

The heat ray (2) attached to the heat insulating substrate is divided into a metal heating element and a non-metal heating element. Examples of the metal heating element include nickel metal, inconel, kanthal, and nikrothal, and the non-metallic heating element includes silicon carbide or pyromax. Generally, a metal heating element is excellent in workability and is widely used. A heating element is selected according to a design method of a heating substrate, and is attached to a thermal insulating substrate in the form of hot wire attachment, direct printing or insulation coating. In the present invention, a nickel-based alloy is used as an example of a heating wire to fabricate a substrate heater, but the present invention is not limited thereto.

The protective substrates 3 and 4 are generally made of the same material as that of the heat insulating substrate, and the heat insulating material and the terminal block are provided on the heat insulating substrate, and then the two substrates are pressed on the upper and lower surfaces of the heat insulating substrate. The surface to which the hot wire is attached is the upper surface and the opposite surface is the lower surface. For upper surface crimping, a pattern with the same depth as the bolt head is used so that the head of the bolt can be inserted into the same position as the insulating substrate in the installation of the terminal block. The protective substrate to be bonded to the lower surface is prepared by previously forming a through hole for a terminal block at the same position as the adiabatic substrate and then pressing it. The protective substrate bonding of the substrate heater used in the low-temperature baking apparatus at 200 ° C or lower uses a high-temperature epoxy rather than a squeeze.

The thermally conductive substrate is bonded to a surface of an upper protective substrate attached to an upper part of a heat insulating substrate 1 to which a heat ray is applied to uniformize the thermal diffusion, and is generally selected to be larger than the size of the substrate to be baked. The thermal conductive substrate is a thermal conductive substrate of a low-priced baking apparatus. Aluminum, copper, Inconel, STS, etc., which are metal substrates, are mostly used. Aluminum nitride, sapphire or quartz substrates such as nonmetal systems are used for high- In general, a metal substrate is used economically, but a ceramic substrate such as aluminum nitride is recently used due to a difference in thermal expansion from a heat insulating substrate.

The power supply unit, the temperature control unit, the control display unit, and the baking unit case, which are included in the high-temperature baking apparatus, are composed of parts and systems used for manufacturing a conventional semiconductor baking apparatus.

FIG. 1 is a perspective view of a substrate heater in which a heat wire is attached to a heat insulating substrate, both ends of a heat wire are fixed to the electric applying unit by using a terminal block, and a protective substrate is pressed and bonded to both surfaces of the substrate. The substrate heater is manufactured by uniformly attaching the heat ray density uniformly to the outer surface of the mica heat-insulating substrate 1 according to a pattern previously formed at the diameter of the heat ray 2, or by attaching the heat ray more closely to the outside than the inside in consideration of the size of the heat insulating substrate. At this time, terminal blocks 5 and 6 serving as both a power supply and a hot wire fixing are provided at the edge of the heat insulating board to which the hot wire is attached.

The hot wire is formed in a concentric circle so as to be installed from the inside to the outside and densely to the outside so that both ends of the hot wire reach the electric applicator 8 located at the edge of the heat insulating board. This is because the central part where the hot wire is installed is trapped by the heat generated from the external hot wire and is not easily cooled due to the influence of the outside air, but the outer part can be easily contacted with the outside air. When the heat ray is adhered to a heat insulating substrate having a small outer diameter, it may be attached with a uniform heat ray density.

When a heat ray is adhered to a heat insulating substrate having an outer diameter of more than 200 mm, the heat ray can be divided into heating regions according to the area of the heat insulating substrate, and the number of terminal blocks is twice the number of heating regions. A large area of the heating substrate can maintain a uniform temperature throughout the entire area by increasing the density of heat rays on the outside.

Fig. 2 is a cross-sectional view of a heat-insulating board bonded to a heat-insulating board using a screw-shaped terminal block. The terminal boards 5 and 6 of the heat insulating board 1 to which the hot wire is attached are screws having an angled bolt head 3 and a through hole 10 at the bottom of the bolt head. Since it passes through the hole 10 and is fixed by the two nuts 7 and 8, it is possible to prevent the contact failure of the electricity applying portion due to the screw loosening caused by the long time heating at a high temperature, It is possible to prevent the thermal deformation phenomenon due to the difference of the thermal expansion coefficient.

3 is a perspective view of a terminal block having a screw shape. The terminal block is manufactured by using a conventional bolt nut manufacturing method.

The hot wire is fixed to the electrical connection part between the first nut and the second nut of the terminal block from the power supply of the power supply part, generates heat by receiving power, and supplies heat to the thermally conductive substrate bonded to the substrate heater.

The thermally conductive substrate of the baking apparatus acts to perform uniform thermal diffusion, and includes a plurality of temperature sensors on the upper surface, and a predetermined temperature is controlled by a temperature controller by a temperature controller having a feedback circuit.

Although a variety of materials can be used for the heat insulating substrate, it is preferable to use a mica which is stable at 500 ° C and can withstand a high temperature of 900 ° C and is inexpensive. Mica is also called mica and the substrate type is obtained from muscovite or phlogopite mica. It is a kind of silicate minerals. It is excellent in heat insulation function and electric insulation, and is used as a heater structure by attaching heat wire. It is also used as an insulation material of a capacitor.

Various materials can be used for the hot wire, but it is preferable to use a nickel alloy. Nickel alloys vary in the ratio of nickel to fused metal. The nickel and chromium contents of nickel and chromium are 80% and 20%, respectively, with a melting point of 1400 ° C and a thermal expansion coefficient of 14E-6 / K. Inconel is a super alloy made of nickel and chrome as main alloys and made of other metals such as iron, aluminum, or non-metals such as silicon and carbon. Inconel has oxidation and corrosion protection and is used in extreme situations. Chandelier is made of iron-chrome-aluminum alloy and iron-chrome is produced by mixing small amount of aluminum with main metal content. The duct delamination has a melting point of 1200 ° C and is suitable for making a heater for a high temperature.

The terminal block uses the same or similar material as the hot wire to prevent the distortion due to the difference in thermal expansion coefficient.

The present invention is used as a heater of a high-temperature baking apparatus. The semiconductor wafer or the glass substrate is placed on the thermally conductive substrate of the high-temperature baking apparatus after the photosensitive liquid is applied, and the cured and hardened substrate is transferred manually or automatically to the next process by the wafer tweezers or the air bonding apparatus.

The substrate heater according to the present invention can be used for a high-temperature baking apparatus used in a semiconductor process, a low-temperature baking apparatus for semiconductor processing, or various baking apparatuses requiring a heater.

Although the substrate heater according to the present invention has been described with reference to the drawings, the present invention is not limited to the embodiments and drawings described in this specification, and various modifications may be made by those skilled in the art to be.

1: Insulating substrate 2: Hot wire
3: upper surface protection substrate 4: lower surface protection substrate
5: Bolt head 6: Support
7: first nut 8: second nut
9: Terminal through hole 10: Bolt head pattern
11: Electricity application part 12: Align mark
13: through hole for bonding A 14: through hole for bonding B
15: thermally conductive substrate 16: terminal portion

Claims (6)

A substrate heater for a high-temperature baking apparatus used in a semiconductor or display process,
A heat insulating substrate having pattern grooves formed on one surface thereof with a heat ray diameter and attached with heat rays;
A terminal block having a through hole formed in the lower part of the head of the bolt and inserted into the end of the hot wire, fixed to the edge of the heat insulating board with a nut,
And a protective substrate bonded to upper and lower portions of the heat insulating substrate to protect and insulate heat rays,
The bolt head of the terminal block has an angular shape and a groove having the same angular shape is formed on the protective board so as to be fitted,
Wherein the substrate is heated by using a double nut to prevent the substrate from being loosened by thermal deformation. The method according to claim 1,
Wherein the double nuts are fastened with threads having different directions. ≪ RTI ID = 0.0 > 15. < / RTI > The method according to claim 1,
Further comprising a thermally conductive substrate bonded to an upper portion of the substrate heater,
Wherein a plurality of temperature sensors are attached to an upper portion of the thermally conductive substrate, and a substrate temperature is controlled by a temperature controller having a feedback circuit. The method according to claim 1,
Wherein the hot wire is formed of a nickel alloy. The method according to claim 1,
Wherein the heat insulating substrate and the protective substrate are mica. The method of claim 3,
Wherein the thermally conductive substrate is AlN.

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